TY - JOUR
T1 - Shape-supervised Dimension Reduction
T2 - Extracting Geometry and Physics Associated Features with Geometric Moments
AU - Khan, Shahroz
AU - Kaklis, Panagiotis
AU - Serani, Andrea
AU - Diez, Matteo
AU - Kostas, Konstantinos
N1 - Funding Information:
The first two authors are thankful for the support and funding received from the EU Horizon-2020 Research and Innovation Programme under the Marie Skłodowska-Curie grant agreement No. 860843 – GRAPES: Learning, Processing and Optimising Shapes. The third and fourth authors are grateful to the US Office of Naval Research Global for its support through grants N62909-11-1-7011 and N62909-21-1-2042 . The last author is supported by The Nazarbayev University FDCRGP 2022–24, Kazakhstan funded project: SOFFA - PHYS: Shape Optimisation of Free-form Functional surfaces using isogeometric Analysis and Physics-Informed Surrogate Models, Grant No. 11022021FD2927 .
Publisher Copyright:
© 2022 The Author(s)
PY - 2022/9
Y1 - 2022/9
N2 - In shape optimisation problems, subspaces generated with conventional dimension reduction approaches often fail to extract the intrinsic geometric features of the shape that would allow the exploration of diverse but valid candidate solutions. More importantly, they also lack incorporation of any notion of physics against which shape is optimised. This work proposes a shape-supervised dimension reduction approach. To simultaneously tackle these deficiencies, it uses higher-level information about the shape in terms of its geometric integral properties, such as geometric moments and their invariants. Their usage is based on the fact that moments of a shape are intrinsic features of its geometry, and they provide a unifying medium between geometry and physics. To enrich the subspace with latent features associated with shape's geometrical features and physics, we also evaluate a set of composite geometric moments, using the divergence theorem, for appropriate shape decomposition. These moments are combined with the shape modification function to form a Shape Signature Vector (SSV) uniquely representing a shape. Afterwards, the generalised Karhunen–Loève expansion is applied to SSV, embedded in a generalised (disjoint) Hilbert space, which results in a basis of the shape-supervised subspace retaining the highest geometric and physical variance. Validation experiments are performed for a three-dimensional wing and a ship hull model. Our results demonstrate a significant reduction of the original design space's dimensionality for both test cases while maintaining a high representation capacity and a large percentage of valid geometries that facilitate fast convergence to the optimal solution. The code developed to implement this approach is available at https://github.com/shahrozkhan66/SSDR.git.
AB - In shape optimisation problems, subspaces generated with conventional dimension reduction approaches often fail to extract the intrinsic geometric features of the shape that would allow the exploration of diverse but valid candidate solutions. More importantly, they also lack incorporation of any notion of physics against which shape is optimised. This work proposes a shape-supervised dimension reduction approach. To simultaneously tackle these deficiencies, it uses higher-level information about the shape in terms of its geometric integral properties, such as geometric moments and their invariants. Their usage is based on the fact that moments of a shape are intrinsic features of its geometry, and they provide a unifying medium between geometry and physics. To enrich the subspace with latent features associated with shape's geometrical features and physics, we also evaluate a set of composite geometric moments, using the divergence theorem, for appropriate shape decomposition. These moments are combined with the shape modification function to form a Shape Signature Vector (SSV) uniquely representing a shape. Afterwards, the generalised Karhunen–Loève expansion is applied to SSV, embedded in a generalised (disjoint) Hilbert space, which results in a basis of the shape-supervised subspace retaining the highest geometric and physical variance. Validation experiments are performed for a three-dimensional wing and a ship hull model. Our results demonstrate a significant reduction of the original design space's dimensionality for both test cases while maintaining a high representation capacity and a large percentage of valid geometries that facilitate fast convergence to the optimal solution. The code developed to implement this approach is available at https://github.com/shahrozkhan66/SSDR.git.
KW - Computer-aided design
KW - Design space
KW - Dimensionality reduction
KW - Geometric moment invariants
KW - Shape optimisation
KW - Subspace
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U2 - 10.1016/j.cad.2022.103327
DO - 10.1016/j.cad.2022.103327
M3 - Article
AN - SCOPUS:85131116804
SN - 0010-4485
VL - 150
JO - CAD Computer Aided Design
JF - CAD Computer Aided Design
M1 - 103327
ER -